何猛辉

• 单位：国家同步辐射实验室

• 地址：安徽省合肥市蜀山区合作化南路42号

• 邮编：230029

• 邮箱：hemenghui@ustc.edu.cn

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• 个人简历
  

• 何猛辉，1993年出生，2022年博士毕业于复旦大学。

• 工作经历

• 2022.06 -- 2024.05 中国科学技术大学 博士后

• 2024.05 -- 至今 中国科学技术大学国家同步辐射实验室 特任高级工程师 软X射线成像线站（BL07W）运行负责人

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• 研究方向

• 1. X射线成像技术

• 2. X射线聚焦与波导传输

• 3. 光纤/波导设计与制作

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• 主持基金

• 1. 2023 安徽省博士后研究人员科研活动经费资助项目，主持

   

• 论文专著

1) He M., Zeng J., Chen Z., Zhang X., Zhu X., Jing C., Chang C*., and Shi Y*. Low-Loss Flexible Polarization-Maintaining Hollow Waveguide for Linearly Polarized 100 GHz Radiation Transmission and Subwavelength Imaging. Journal of Lightwave Technology (2022).

2) He M., Zeng J., Zhang X., Zhu X., Jing C., Chang C*. and Shi Y*. Transmission and imaging characteristics of flexible gradually tapered waveguide at 0.3 THz. Optics Express (2021).

3) He M., Chen Z., Zeng J., Chen K, Liu S., Zhang X., Zhu X., Jing C., Chang C*. and Shi Y*. Design, fabrication, and characterization of a single-polarization single-mode flexible hollow waveguide for low loss millimeter wave propagation. Optics Express (2022).

4) Li F., He M.*, Zhang X., Chang M., Wu Z., Liu Z. and Chen H. Elliptical As2Se3 filled core ultra-high-nonlinearity and polarization maintaining photonic crystal fiber with double hexagonal lattice cladding. Optical Materials (2018).

5) Li F., He M.*, Zhang X., Chang M. and Wu Z. Ultra-high birefringence and nonlinearity photonic crystal fiber with a nanoscale core shaped by an air slot and silicon strips. Optical Fiber Technology (2020).

6) Zhang X., He M., Chang M., Chen H., Chen N., Qi N., Yuan, M. and Qin X. Dual-cladding high-birefringence and high-nonlinearity photonic crystal fiber with As2S3 core. Optics Communications (2018).

7) Wang T., He M., Shen K, Liu W. and Tian C*. Learned regularization for image reconstruction in sparse-view photoacoustic tomography. Biomedical Optics Express (2022).

8) Zeng J., He M., Zhang X., Zhu X. and Shi Y*. Simulation methods and transmission characteristics of dielectric-coated metallic waveguides from mid-infrared to millimeter waves. Applied Physics B: Lasers and Optics (2021).

9) Chen Z., Zeng J., He M., Zhu X. and Shi Y*. Portable ppb-level carbon dioxide sensor based on flexible hollow waveguide cell and mid-infrared spectroscopy. Sensors and Actuators B: Chemical (2022).

10) Tan Y., Zhao F., He M., Wang Y., Zhou W., Zhang J., Zhu M., Shi Y. and Yu J. Transmission of High-Frequency Terahertz Band Signal Beyond 300 GHz Over Metallic Hollow Core Fiber. Journal of Lightwave Technology (2022).

11) Peng C., Zheng J., He M., Zhao Z., Zhang X., Zhu X., Jing C., Chang C. and Shi Y*. Development of flexible mid-infrared light delivery system with bio-probe for beam control. Optics and Lasers in Engineering (2020).

12) Ding J., Tan Y., Wang Y., Zhang J., He M., Zhao F., Zhao L., Zhou W., Shi Y., Zhu M. and Yu J. 352-Gbit/s single line rate THz wired transmission based on PS-4096QAM employing hollow-core fiber. Digital Communications and Networks (2022).

13) Chang M., Zhang Z., Zhang X., He M., Qiu Z. and Wu J. The configuration of DMD and the maximum intensity projection method for improving contrast in DMD‐based confocal microscope. Microscopy Research and Technique (2018).